High-K gate dielectric process with process with self aligned damascene contact to damascene gate and a low-k inter level dielectric

ABSTRACT

A method of fabricating a transistor having shallow source and drain extensions utilizes a self-aligned contact. The drain extensions are provided through an opening between a contact area and the gate structure. A high-K gate dielectric material can be utilized. P-MOS and N-MOS transistors can be created according to the disclosed method.

CROSS REFERENCE TO RELATED APPLICATIONS

This patent application is related to U.S. application Ser. No. 09/255,203 filed by Yu, entitled “Step Drain and Source Junction Formation” U.S. application Ser. No. 09/255,604 filed by Yu, entitled “A Process for Forming Ultra-Shallow Source/Drain Extensions” and U.S. application Ser. No. 09/303,693 by Xiang et al., entitled “Self-Aligned Source and Drain Extensions Fabricated in a Damascene Contact and Gate Process” and U.S. application Ser. No. 09/303.694 by Xiang et al., entitled “A High-K Gate Dielectric Process With Self Aligned Damascene Contact to Damascene Gate”, all assigned to the assignee of the present invention. This patent application is also related to U.S. application Ser. No. 09/187,630, filed on Nov. 6, 1998 by Yu, entitled “Dual Amorphization Implant Process for Ultra-Shallow Drain and Source Extensions”, U.S. application Ser. No. 09/187,890, filed on Nov. 6, 1998, by Yu, et al., entitled “A Method of Fabricating an integrated Circuit with Ultra-Shallow Source/Drain Extension”, U.S. application Ser. No. 09/187,172, filed on Nov. 6, 1998 by Yu, entitled “Recessed Channel Structure for Manufacturing Shallow Source Drain Extension” and U.S. application Ser. No. 09/187,635 filed on Nov. 6, 1998 by Yu, et al., entitled “A Damascene Process for Forming Ultra-Shallow Source/Drain Extensions and Pocket in ULSI MOSFET”, all assigned to the assignee of the present invention.

BACKGROUND OF THE INVENTION

The present invention relates to integrated circuits (ICs) and methods of manufacturing integrated circuits. More particularly, the present invention relates to a method of manufacturing integrated circuits having transistors with self aligned contacts.

Integrated circuits (ICs), such as, ultra-large scale integrated (ULSI) circuits, can include as many as one million transistors or more. The ULSI circuit can include complementary metal oxide semiconductor (CMOS) field effect transistors (FETS). The transistors can include semiconductor gates disposed between drain and source regions. The drain and source regions are typically heavily doped with a P-type dopant (boron) or an N-type dopant (phosphorous).

The drain and source regions generally include a thin or shallow extension that is disposed partially underneath the gate to enhance the transistor performance. Shallow source and drain extensions help to achieve immunity to short-channel effects which degrade transistor performance for both N-channel and P-channel transistors. Short-channel effects are among the most important scaling issues for mainstream CMOS technology and can cause threshold voltage roll-off and drain-inducted barrier lowering. Shallow source and drain extensions and, hence, controlling short-channel effects, are particularly important as transistors become smaller.

Conventional techniques utilize a double implant process to form shallow source and drain extensions. According to the conventional process, the source and drain extensions are formed by providing a transistor gate structure without sidewall spacers on a top surface of a silicon substrate. The silicon substrate is doped on both sides of the gate structure via a conventional doping process, such as, a diffusion process or ion implantation process. Without the sidewall spacers, the doping process introduces dopants into a thin region (i.e., just below the top surface of the substrate) to form the drain and source extensions as well as to partially form the drain and source regions.

After the drain and source extensions are formed, silicon dioxide spacers, which abut lateral sides of the gate structure, are provided over the source and drain extensions. The substrate is doped a second time to form the deeper source and drain regions. The source and drain extensions are not further doped due to the blocking capability of the silicon dioxide spacer.

As transistors disposed on integrated circuits (ICs) become smaller, transistors with shallow and ultra-shallow source/drain extensions have become more difficult to manufacture. For example, smaller transistors should have ultra-shallow source and drain extensions (less than 30 nanometer (nm) junction depth). Forming source and drain extensions with junction depths of less than 30 nm is very difficult using conventional fabrication techniques.

Conventional ion implantation and diffusion doping techniques make transistors on the IC susceptible to short-channeling effects, which result in a dopant profile tail distribution that extends deep into the substrate. Also, conventional ion implantation techniques have difficulty maintaining shallow source and drain extensions because point defects generated in the bulk semiconductor substrate during ion implantation can cause the dopant to more easily diffuse (transient enhanced diffusion, TED). The diffusion often extends the source and drain extension vertically in to the bulk semiconductor substrate.

As transistors disposed on integrated circuits (ICs) become smaller (e.g., transistors with gate lengths approaching 50 nm), CMOS fabrication processes have considered a two-dimensional channel-doping technique. A two-dimensional doping implant can form a channel-doping profile in the lateral direction that is non-uniform and a channel-doping profile in the vertical direction that is a super-steep retrograded channel-doping profile. The two-dimensional channel-doping profile is critical to scaling (i.e., proportional operation and structural elements in the ultra-small dimensions of a sophisticated transistor).

The two-dimensional channel doping profile is conventionally formed with deep pocket implants which surround the entire source and the entire drain. The implants have an opposite conductivity type to that of the source and drain and form a “halo-like” structure around the border of the source and drain. The halo-like structure increases the doping concentration near the junction of the source and drain. Increased doping concentration near the junction of source and drain degrades (i.e., increases) the source/drain junction capacitance (e.g., parasitic capacitance). Increased parasitic capacitance reduces the speed of the transistor.

Thus, shallow extensions and deep pocket implants are utilized to alleviate short channel effects. However, the formation of shallow extensions is difficult as transistors become smaller and pocket implants can adversely effect the speed of transistors when fabricated according to conventional processes.

Yet another major problem associated with CMOS scaling is related to conventional gate dielectric materials disposed under the gate conductor.

Generally, conventional gate dielectric materials, such as, silicon dioxide are less reliable as transistor size is decreased. For example, silicon dioxide is subject to high leakage current caused by “direct tunneling effect.” Generally, as channel lengths approach 70 nanometers (nm) or less, high dielectric constant (k) dielectric materials must replace silicon dioxide dielectric materials.

High k dielectric materials cannot be utilized in conventional CMOS processes due to the thermal instability associated with the molecular structure of high k dielectric materials. High temperature treatments, such as, source/drain implantation activation annealing (typically 1050° C. for 10 seconds) can cause reactions between the high k dielectric materials and silicon. Also, high k dielectric materials can change phases (amorphous to crystalline) in response to the high temperature treatments. For example, one high k dielectric material, tantalum pentaoxide (Ta₂O₅), changes phase from an amorphous material to a crystalline material at approximately 800° C. Crystalline Ta₂O₅ material has a high leakage current.

Still another problem associated with CMOS scaling involves spacings between gate structures and contacts. Contacts are required in an IC device to provide electrical connections between layers or levels of the integrated circuit device. Semiconductor devices typically include a multitude of transistors which are coupled together in particular configurations through contacts.

Contacts are generally coupled to the source region and/or drain region of the transistors disposed on the integrated circuit. The contact is often connected to the source and drain region via a silicide layer. The silicide layer is generally formed in a high temperature process. The silicide layer reduces drain/source series resistance.

In conventional processes, contacts must be spaced from the gate conductor by a minimum acceptable distance (often at least one minimum lithographic feature). Contacts must be spaced apart from the gate structure so alignment errors do not result in a shorting or severe crosstalking or stacked gate with the source contact or the drain contact. As lithographic feature sizes are reduced according to advanced fabrication processes, the spacing between the contacts and the gate structure becomes even more critical because slight alignment errors can cause a short circuit. The spacing between the contact and gate contributes to the overall size of the transistor and hence, the size of the IC.

Thus, there is a need for a process which prevents misalignment between the contact and gate and allows the spacing between the contact and the gate to be reduced. Further, there is a need for a method of manufacturing an integrated circuit with a high-k gate dielectric layer and a low-k interlevel dielectric layer. Even further still, there is a need for transistors that have shallow junction source and drain extensions that can utilize high-k dielectric materials.

SUMMARY OF THE INVENTION

The present invention relates to a process for fabricating an integrated circuit comprising forming a polysilicon pattern on a substrate. The polysilicon pattern has a first spacing between a gate region and a first contact region and a second spacing between the gate region and a second contact region. The method further includes depositing a low-k dielectric material in the first spacing and the second spacing, removing the polysilicon patter, and depositing a gate dielectric and a gate conductor over a gate region.

The present invention still further relates to a method of fabricating an integrated circuit on a substrate. The method includes etching a conductive layer to provide a first hole and a second hole, depositing a low-k dielectric material in the first hole and the second hole, removing a remaining portion of the conductive layer, and providing a gate conductor over the gate location.

The present invention still further relates to a damascene method of fabricating an integrated circuit on a substrate. The substrate has a first conductive structure separated from a second conductive structure by a first space. The substrate also has a third conductive structure separated from the second conductive structure by a second space. The second conductive structure is at a gate location. The method includes the steps of forming a shallow source region below the first space and a shallow and drain region below the second space, depositing a low-k dielectric material in the first space and the second space, etching the first conductive structure and the third conductive structure, forming a deep source region and a deep drain region, etching the second conductive structure and depositing a gate conductor over the gate location.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the present invention will hereafter be described with reference to the accompanying drawings, wherein like numerals denote like elements, and:

FIG. 1A is a cross-sectional view of a portion of an integrated circuit including an N-channel transistor with shallow source/drain extensions in accordance with an exemplary embodiment of the present invention;

FIG. 1B is a cross-sectional view of a portion of the integrated circuit including a P-channel transistor with shallow source/drain extensions in accordance with another exemplary embodiment of the present invention;

FIG. 2A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a shallow trench isolation step.

FIG. 2B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the shallow trench isolation step.

FIG. 3A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a polysilicon deposition step;

FIG. 3B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the polysilicon deposition step;

FIG. 4A is a cross-sectional view of the portion of the illustrated circuit illustrated in FIG. 1A, showing a polysilicon patterning step;

FIG. 4B is a cross-sectional view of the portion of the illustrated circuit illustrated in FIG. 1B, showing the polysilicon patterning step;

FIG. 5A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a shallow junction implant step for N-channel transistors;

FIG. 5B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the shallow junction implant step for N-channel transistors;

FIG. 6A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a shallow junction implant step for P-channel transistors;

FIG. 6B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the shallow junction implant step for P-channel transistors;

FIG. 7A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a silicon dioxide deposition and chemical mechanical polish step;

FIG. 7B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the silicon dioxide deposition and chemical mechanical polish step;

FIG. 8A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a polysilicon removal step;

FIG. 8B is a cross-section view of the portion of the integrated circuit illustrated in FIG. 1B, showing the polysilicon removal step;

FIG. 9A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a deep source/drain implantation step for N-channel transistors;

FIG. 9B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the deep source/drain implantation step for N-channel transistors;

FIG. 10A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a deep source/drain junction implant step for P-channel transistors;

FIG. 10B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the deep source/drain junction implant step for P-channel transistors;

FIG. 11A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a gate dielectric and gate metal deposition step;

FIG. 11B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the gate dielectric and gate metal deposition step;

FIG. 12A is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1A, showing a gate metal removal step;

FIG. 12B is a cross-sectional view of the portion of the integrated circuit illustrated in FIG. 1B, showing the gate metal removal step;

FIG. 13A is a cross-sectional view of the integrated circuit illustrated in FIG. 1A, showing a nickel deposition step; and

FIG. 13B is a cross-sectional view of the integrated circuit illustrated in FIG. 1B, showing the nickel deposition step.

DETAILED DESCRIPTION OF THE PREFERRED EXEMPLARY EMBODIMENTS

FIGS. 13A-13B illustrate an advantageous complementary metal oxide semiconductor (CMOS) fabrication damascene process for forming P-channel and N-channel transistors on a substrate. FIGS. 1A-13A show the process associated with a portion of the integrated circuit including an N-channel transistor. FIGS. 1B-13B show the process with respect to a portion of the integrated circuit including an N-channel transistor. The advantageous process and transistor structure is described below with reference to FIGS. 1A-13B as follows.

With reference to FIGS. 1A and 1B, an integrated circuit 15 includes an N-channel transistor 16A (FIG. 1A) disposed on a portion 17A of semiconductor substrate 14 and a P-channel transistor 16B (FIG. 1B) disposed on a portion 17B of semiconductor substrate 14. Portion 17A is preferably within a P-well or P-type region (P−) of substrate 14. Alternatively, entire substrate 14 can be lightly doped with P-type dopants (P−). Substrate 14 associated with portion 17B is lightly doped with N-type dopants (N−). Portion 17B is preferably part of an N-well or N-type region (N−) associated with substrate 14.

Semiconductor substrate 14 is preferably a single crystal silicon material, such as, a single crystal silicon wafer. Transistors 16A and 16B can be field effect transistors, such as, metal oxide semiconductor field effect transistors (MOSFETs). Transistors 16A and 16B preferably have gate lengths which are less than 100 nm (e.g. approaching 50 nm) and are part of an ultra-large scale integrated (ULSI) circuit that includes 1,000,000 or more transistors. Transistors 16A and 16B are provided between insulative structures 52. The lateral dimension (e.g., left to right in FIGS. 1A-13B) between structures 52 is preferably less than 1000 nm (e.g. 400-600 nm).

Transistor 16A includes a gate stack or structure 18A, a source region 22A and a drain region 24A. Transistor 16B includes a gate stack or structure 18B, a source region 22B and a drain region 24B. Regions 22A and 24A include deep regions 23A and shallow regions 25A. Regions 22B and 24B include deep regions 23B and shallow regions 25B. Shallow regions 25A and 25B act as source/drain extensions for transistors 18A and 18B, respectively, which help transistors 16A and 16B achieve substantial immunity to short channel effects. Short channel effects can degrade performance of transistors 16A and 16B as well as the manufacturability of the IC associated with transistors 16A and 16B.

Regions 25A and 25B can be ultra-shallow extensions (e.g., junction depths of less than 30 nanometers (nm)), which are thinner than deep regions 23A and 23B. However, regions 25A and 25B can be deeper than 30 nm. Regions 25A and 25B are preferably 10-40 nm deep and 90-130 nm wide.

Regions 23A and 23B are preferably 100 nm (80-250 nm) deep and 80-140 wide. Regions 22A and 24A have a concentration of 10¹⁹⁻²¹ n-type dopants per cm³, and regions 22B and 24B have a concentration of 10¹⁹⁻²¹ p-type dopants per cm³. N-type dopants can be phosphorus (P), arsenic (As), or other dopant, and p-type dopants can be boron (B), boron difluoride (BF₂) or other dopant.

Gate structures 18A and 18B are preferably 100-300 nm high and 80-120 nm wide and include a metal conductor 26, a metal layer or plug 28, a high dielectric constant (k) dielectric layer 30, a metal layer 29, and a gate oxide buffer layer 32. Conductor 26 is preferably a 20-40 nm thick conformal layer of titanium nitride (TiN). Plug 28 is preferably a 50-250 nm thick layer of tungsten (W). Layer 30 is preferably a 2-10 nm thick conformal layer of tantalum pentaoxide (Ta₂O₅) or titanium dioxide (TiO₂). Layer 29 is preferably an 8-12 nm thick layer of metal such as nickel (Ni). Layer 32 is preferably a 4-8 nm thick layer of thermally grown silicon dioxide or deposited silicon nitride (Si₃N₄). Alternatively, layer 26, plug 28, and layer 29 can be replaced with other conductive or semiconductive materials.

Gate stack structure 18A is disposed between an insulative structure 34A and an insulative structure 36A. Gate structure 18B is disposed between an insulative structure 34B and an insulative structure 36B. A contact 40A is provided over drain region 22A, and a contact 42A is provided over a source region 24A. A contact 40B is provided over source region 22B, and a contact 42B is provided over source region 24B. Preferably, contacts 40A, 42A, 40B and 42B are provided over deep regions 23A and 23B, respectively.

Contacts 40A, 42A, 40B and 42B each include a silicide layer 41. Layer 41 is preferably a 20-30 nm thick layer of nickel silicide. Alternatively, other metals, silicides or conductive layers can be utilized.

Insulative structures 34A, 34B, 36A, and 36B serve as an insulative spacer for gate structures 18A and 18B. Structures 34A, 34B, 36A and 36B are preferably 80-120 nm wide and 100-300 nm thick and provide isolation between contacts 40A and 42A and gate structure 18A and between contacts 40B and 42B and gate structure 18B. Structures 34A, 34B, and 36A, and 36B can be conformally deposited by a chemical vapor deposition (CVD) tetraorthosilicate (TEOS) process, and etched back to leave the particular structures for transistors 16A and 16B. Alternatively, structures 34A, 34B, 36A and 36B can be other insulative materials, such as, silicon nitride (Si₃N₄). Insulative structures 53, which are similar to structures 34A, 34B, 36A, and 36B, can be provided over structures 52.

In accordance with another exemplary embodiment of the present invention, conductive structures 34A, 34B, 36A, and 36B can be low-k materials. Low-k materials advantageously reduce capacitive effects associated with contacts 40A, 40B, 42A, and 42B as well as structures 53. The low-k materials (k less than 3, preferably less than 2) can be created from vapor deposition and spin-on coating techniques. For example, vapor deposition of parylene and polynapthalene families of polymers and polytetrafluoroethylene (PTFE) can be utilized to form low-k materials. Alternatively, plasma enhanced chemical vapor deposition (PECVD) and high density plasma CVD of fluorinated SiO2 glass, and amorphous C:F can form the low-k dielectric material. Air gap formation and plasma polymerization of pentafluorostyrene and pulse plasma polymerization of PTFE can also be utilized. Additionally, materials can be deposited by spin coating; spin coating materials include organic polymers (fluorinated or non-fluorinated), inorganic polymers (non porous), inorganic-organic hybrids, or porous materials (xerogels or aerogels). Low-k material synthesis is described in an article entitled “Low-Dielectric-Constant Materials for ULSI Interlayer Dielectric applications”, by Wei William Lee and Paul S. Ho, MRS Bulletin (October, 1997), pages 19-23.

With reference to FIGS. 1A-13B, the fabrication of integrated circuit 15 is described below as follows. In FIGS. 2A and 2B, portions 17A and 17B include structures 52 which are formed by conventional shallow trench isolation (STI) technique. Alternatively, other isolation techniques including local oxidation of silicon (LOCOS) techniques can be utilized to form isolation structures 52. Additionally, well implantation, punch through implantation and threshold adjustment implantation are provided to substrate 14 in accordance with conventional processes. Substrate 14 also includes a pad layer or oxide layer 55 which is thermally grown on substrate 14. Layer 55 preferably has a thickness of 2-5 nm.

With reference to FIGS. 3A and 3B, a conductive layer 38 is deposited over oxide layer 55. Layer 38 is preferably 100-300 nm thick and is utilized as a mask to define insulative structures 34A, 34B, 36A, and 36B, contacts 40A, 40B, 42A and 42B and gate structures 18A and 18B. Layer 38 can be a doped or undoped polysilicon layer deposited by plasma enhanced chemical vapor deposition (PECVD). Alternatively, other deposition techniques and conductive materials can be utilized.

In FIGS. 4A and 4B, conductive layer 38 is selectively etched in a photolithographic process to form structures 62, 64 and 66. Structures 62, 64 and 66 preferably have a width of 80-120 nm and are formed in a deep ultraviolet lithographic process which utilizes a plasma dry etch. Structures 62, 64 and 66 can have a width of less than one minimum lithographic feature by overetching or trim etching.

Structures 62, 64 and 66 define a hole or space 68 and a hole or space 70. Structure 64 is associated with a gate region 118. Space 68 is associated with a source extensions (shallow region 25A of source region 22A and shallow region 25B of source region 22B, FIG. 1A and 1B), and space 70 is associated with a drain extensions (shallow region 25A of drain region 24A and shallow region 25B of drain region 24B, FIGS. 1A and 1B). The polysilicon pattern associated with structures 62, 64 and 66 is formed by providing a photoresist mask and selectively etching layer 38 on substrate 14 to form spaces 68 and 70.

With reference to FIGS. 5A and 5B, substrate 14 undergoes a self-aligned N-MOS implant to provide shallow regions 25A beneath spaces 68 and 70 of portion 17A. Portion 17B, including spaces 68 and 70 and structures 62, 64, and 66, is completely covered by a photolithographic or photoresist mask 80. Mask 80 does not cover portion 17A. Mask 80 protects portion 17B of substrate 14 (underneath mask 80) from the N-MOS implant.

Regions 25A can be formed by implanting phosphorous (P) or Arsenic (As) (or other n-type dopant) to a depth of 10-40 nm with low energy (1-10 KeV (kiloelectron volts)) at a dose of 5×11¹⁴−2×10¹⁵ dopants per centimeter (cm) squared and annealing. Annealing can include rapid thermal annealing (RTA), laser annealing, or pulse annealing. Alternatively, arsenic can be utilized at lower energy levels (5 KeV or less).

The N-MOS implant can be provided at a 90 degree angle or other angle to form regions 25A. Dopants associated with the N-MOS implant can laterally diffuse a distance of 30-60 percent of the junction depth within substrate 14. Regions 25A preferably have a concentration of 10¹⁹⁻²¹ dopants per centimeter cubed.

Additionally, other implants can be provided to portion 17A. For example, a halo or pocket implants or other dopant profile engineering techniques can be provided through spaces 68 and 70. Preferably, halo or pocket implants are provided before the N-MOS implant to form a two-dimensional channel doping profile. The halo implant provides p-type dopants through spaces 68 and 70 of portion 17A to a depth below regions 25A (preferably below regions 23A). The halo implant is advantageously confined by spaces 68 and 70 so the resulting pocket regions do not adversely effect regions 25A and do not increase junction capacitance. Layer 80 is removed by an etching, stripping, or other removal process.

With reference to FIGS. 6A and 6B, a self-aligned P-MOS implant is provided to substrate 14 to provide shallow regions 25B beneath spaces 68 and 70 of portion 17B. Portion 17A, including spaces 68 and 70 and structures 62, 64 and 66, is completely covered by a photolithographic or photoresist mask 82. Mask 82 does not cover portion 17B. Mask 82 protects portion 17A of substrate 14 (underneath mask 82) from the P-MOS implant.

Regions 25B can be formed by implanting boron (B) to a depth of 10-40 nm (or other p-type dopant) with a low energy (1-10 KeV) at a dose of 5×10¹⁴−2×10¹⁶ dopants per cm squared and by annealing. Annealing can include RTA, laser annealing, or annealing. Alternatively, boron difluoride (BF₂) can be utilized as a p-type dopant at lower energy levels (5 KeV or less). Regions 25B preferably have a concentration of 10¹⁹⁻²¹ dopants per centimeter cubed.

Additionally, other implants can be provided to portion 17B. For example, halo or pocket implants or other dopant profile engineering techniques can be provided through spaces 68 and 70. Preferably halo or pocket implants are provided before the P-MOS implant to form in a two-dimensional doping profile. The halo implant provides n-type dopants through spaces 68 and 70 of portion 17B to a depth below regions 25B (preferably below regions 23B). The halo implant is advantageously confined by spaces 68 and 70 so the resulting pocket regions do not adversely affect regions 25B and do not increase junction capacitance.

The P-MOS implant can be performed at a 90° angle or other angle to form regions. Dopants associated with the P-MOS implant laterally diffuse a distance of 30-60 percent of the junction depth within substrate 14. Regions 23B have a concentration of 10¹⁹⁻²¹ P-type dopants per cm cubed. Alternatively, the P-MOS implant described with reference to FIG. 6A-B can be performed before the N-MOS implant described with reference to FIGS. 5A and 5B.

With reference to FIGS. 7A and 7B, layer 82 (FIGS. 6A and 6B) is removed and an insulative layer is deposited in a conformal deposition process to fill spaces 68 and 70. The insulative layer is subject to a chemical mechanical polish (CMP) to leave insulative structures 34A and 34B and insulative structures 36A and 36B in spaces 68 and 70, respectively, and structures 53 above structures 52. Alternatively, other space filling techniques can be utilized to provide insulative material in spaces 68 and 70 (FIGS. 6A and 6B).

Preferably, the insulative layer associated with structures 34A, 34B, 36A, 36B is deposited in a TEOS process by CVD. Insulative structures 34A, 34B, 36A, 36B can be silicon dioxide or silicon nitride. Structures 34A, 34B, 36A, 36B are shown including layer 55 for simplicity. According to another alternative embodiment of the present invention, a low k dielectric material is utilized. The low k dielectrical material is preferably hydrogen silsesquioxane (HSQ), spin-on-glass (SOG) or benzocyclobutene (BCB) Low k dielectric materials are discussed with reference to FIGS. 1A and 1B.

With reference to FIGS. 8A and 8B, conductive structures 62, 64 and 66 are removed from portions 17A and 17B leaving holes or spaces 92, 94 and 96. Layer 55 remains in spaces 92, 94 and 96. Spaces 92, 94 and 96 are preferably 80-120 nm wide. Spaces 92, 94, and 96 can be less than one lithographic feature. Conductive structures 62, 64 and 66 can be removed in an isotropic dry etching or chemical-wet etching process selective to polysilicon with respect to silicon dioxide.

With reference to FIGS. 9A and 9B, portion 17B is completely covered by a photolithographic or photoresist mask 112 and spaces 94 of portion 17A is covered by mask 112. Mask 112 is selectively etched in a photolithographic process to leave mask 112 in opening 94 but not in spaces 92 and 96 of portion 17A.

After mask 112 is selectively etched or patterned, substrate 14 is subjected to an N+ source/drain junction implant to form deep regions 23A beneath spaces 92 and 96. Regions 23A preferably have a concentration of 10¹⁹⁻²¹ N-type dopants per cm cubed. Preferably, arsenic dopants at a dose of 5×10¹⁵ dopants per cm squared are accelerated at an energy of 15-25 KeV to substrate 14. Regions 23A extend to a depth of 100 nm into substrate 14. Mask 112 protects portion 17B and is removed after the N− source/drain junction implant.

With reference to FIGS. 10A and 10B, portion 17A is completely covered by photolithographic or photoresist mask 114. Opening 94 of portion 17B is also covered by mask 114. Mask 114 is selectively etched in a photolithographic process to leave mask 114 in space 94 but not in spaces 92 and 96 of portion 17B.

After mask 114 is selectively etched or patterned, substrate 14 is subjected to a P+ source/drain junction implant to form deep regions 23B beneath spaces 92 and 96. Regions 23B preferably have a concentration of 10¹⁹⁻²¹ n-type dopants per cm cubed. Preferably, boron difluoride dopants at a dose of 1-5×10¹⁵ dopants per cm squared are accelerated at an energy level of 15-25 KeV to substrate 14. Regions 23B extend to a depth of 100 nm into substrate 14. Mask 114 protects portion 17A and is removed after the P-source/drain junction implant. Alternatively, the P+ source/drain junction implant described with reference to FIGS. 10A and 10B can be performed before the N+ source/drain junction implant described with reference to FIGS. 9A and 9B.

With reference to FIGS. 11A and 11B, after mask 114 is removed, a rapid thermal anneal (RTA) is provided to activate implants in regions 23A, 25A, 23B and 25B of portions 17A and 17B. After stripping, layer 55 is removed and a gate oxide formation process is performed. The gate oxide process includes forming a gate oxide layer buffer 32. The gate oxide buffer layer 32 is thermally grown in an O₂ or NO₂ process to a thickness of 4-8 Angstroms and is preferably silicon dioxide.

Layer 32 improves the interface between material 30 and substrate 14. High-K dielectric layer 30 is deposited by CVD over portions 17A and 17B. High-K dielectric layer 30 can be a 20-40 nm thick layer of amorphous Ta₂O₅ material. Layer 30 is preferably conformally deposited in a metal organic CVD process after the RTA step to prevent crystallization of amorphous Ta₂O₅ material. After material 30 is deposited, a 30-40 nm thick layer of metal conductor 36 is conformally deposited by CVD . Metal conductor 26 is preferably TiN. Alternatively, conductor 26 can be polysilicon or a metal.

With reference to FIGS. 12A and 12B, layers 30 and 32 and conductor 26 are selectively etched from spaces 68 and 70. A photolithographic process utilizing layer 124 above gate region 118 preserves layers 30 and 32 and conductor 26 above gate region 118 (e.g., in space 94).

With reference to FIGS. 13A and 13B, mask 124 is removed. After mask 124 is removed, a nickel sputtering process is provided to provide layer 9 (a nickel layer) as an 8-12 nm thick layer within spaces 92 and 96 and above conductor 26. Alternatively, other refractory metals can be utilized.

A nickel silicidation process is utilized to form silicided layers above regions 23A and 23B. The nickel silicidation process includes RTA at temperatures of 500-600° C. Sixty-percent (5-8 nm) of the thickness of layer 29 consumes substrate 14. The low temperature associated with the nickel silicidation process advantageously does not affect layer 30. The silicidation process forms a mono-nickel-silicide which reduces contact resistance.

After layer 29 is provided, plug 28 is deposited by CVD as a tungsten layer 97 on top of layer 29. Alternatively, other refractory metals other than tungsten can be deposited. Layer 97 is utilized for contacts 40A, 40B, 42A, and 42B, as well as plug 28. After deposition of layer 97, substrate 14 is subjected to CMP until a top surface of structures 34A, 36A, 34B and 36B is reached.

The advantageous method of the present invention provides self-aligned shallow source and drain extensions. Self aligned contacts 40B and 42B are formed as well as self-aligned gate structures 18A and 18B and self-aligned source/drain extensions (regions 25A and 25B). The self-aligned nature of contacts 40A, 42A, 40B, and 42B reduce the required lithographic spacing between structures 18A and 18B and contacts 40B and 42B.

It is understood that, while preferred embodiments, examples, materials, and values are given, they are for the purpose of illustration only. The apparatus and method of the invention is not limited to the precise details and conditions disclosed. For example, although a high k dielectric material is mentioned, other materials can be utilized. Thus, changes may be made to the details disclosed without departing from the spirit of the invention, which is defined by the following claims. 

What is claimed is:
 1. A process of fabricating an integrated circuit, comprising: forming a mask pattern on a substrate, the mask pattern having a first spacing between a gate region and a first contact region and a second spacing between the gate region and a second contact region, the first spacing and the second spacing being located at a same transistor, the first spacing and the second spacing being separate from the gate region; depositing a low-k dielectric material having a dielectric constant less than three in the first spacing and the second spacing; removing the mask pattern; and depositing a gate dielectric and a gate conductor over the gate region.
 2. The process of claim 1, wherein the gate dielectric is a high K gate dielectric.
 3. The process of claim 1, wherein the low-k dielectric material is xerogel.
 4. The process of claim 3 further comprising: depositing a nickel material over the gate conductor.
 5. The process of claim 1, wherein the low-k material forms spacers adjacent the gate conductor.
 6. The process of claim 5, wherein the nickel material is removed by a chemical mechanical polish until the low-k dielectric material in the first spacing and the second spacing is reached.
 7. The process of claim 1, wherein the gate dielectric is Ta₂O₅.
 8. A method of fabricating an integrated circuit on a substrate, the method comprising: etching a semiconductive or conductive layer above the substrate to provide a first hole between a gate region and a first contact region for a transistor and a second hole between the gate region and a second contact region for the transistor, the first hole and the second hole not being disposed over the gate region; depositing a low-k dielectric material having a dielectric constant less than three in the first hole and the second hole; removing a remaining portion of the semiconductive or conductive layer at the gate region; and providing a gate conductor over the gate region.
 9. The method of claim 8, wherein the gate conductor is also provided at a second location associated with a first contact and at a third location associated with a second contact.
 10. The method of claim 9 further comprising: selectively removing the gate conductor from the second location and the third location.
 11. The method of claim 10 further comprising: depositing a nickel material at the second location and at the third location.
 12. The method of claim 11, wherein the nickel is also provided above the gate conductor.
 13. The method of claim 9, wherein the low-k dielectric material is xerogel.
 14. The method of claim 8 further comprising: thermally annealing the substrate after a doping step and before the providing step.
 15. A method of fabricating an integrated circuit on a substrate, the method comprising: providing the substrate having a first sacrificial structure separated from a second sacrificial structure by a first space, the substrate having a third sacrificial structure separated from the second sacrificial structure by a second space, the second sacrificial structure being at a gate location of a transistor, the first, second and third sacrificial structures being a conductive or semiconductive material; forming a shallow source region below the first space and a shallow drain region below the second space; depositing a low-k insulative material having a dielectric constant less than three in the first space and the second space; etching the first sacrificial structure and the third sacrificial structure to leave a third space and a fourth space; forming a deep source region through the third space and a deep drain region through the fourth space for the transistor; etching the second sacrificial structure; and depositing a gate conductor over the gate region.
 16. The method of claim 15, wherein a gate dielectric is deposited before the gate conductor.
 17. The method of claim 16, wherein the gate conductor is a metal.
 18. The method of claim 15, wherein the shallow source region is less than 70 nanometers deep.
 19. The method of claim 15, wherein the first space is less than a minimum lithograph feature.
 20. The method of claim 1, wherein the dielectric constant is less than two.
 21. The method of claim 8, wherein the dielectric constant is less than two.
 22. The method of claim 15, wherein the dielectric constant is less than two. 